/**
 * \file
 *
 * \brief SAM USB HPL
 *
 * Copyright (C) 2015-2017 Atmel Corporation. All rights reserved.
 *
 * \asf_license_start
 *
 * \page License
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are met:
 *
 * 1. Redistributions of source code must retain the above copyright notice,
 *    this list of conditions and the following disclaimer.
 *
 * 2. Redistributions in binary form must reproduce the above copyright notice,
 *    this list of conditions and the following disclaimer in the documentation
 *    and/or other materials provided with the distribution.
 *
 * 3. The name of Atmel may not be used to endorse or promote products derived
 *    from this software without specific prior written permission.
 *
 * 4. This software may only be redistributed and used in connection with an
 *    Atmel microcontroller product.
 *
 * THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
 * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
 * EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
 * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
 * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 * POSSIBILITY OF SUCH DAMAGE.
 *
 * \asf_license_stop
 *
 */

#include <compiler.h>
#include <hal_atomic.h>
#include <hpl_usb.h>
#include <hpl_usb_device.h>

#include <hpl_usb_config.h>
#include <string.h>
#include <utils_assert.h>

/**
 * \brief Dummy callback function
 * \return Always false.
 */
static bool _dummy_func_no_return(uint32_t unused0, uint32_t unused1)
{
	(void)unused0;
	(void)unused1;
	return false;
}

/**
 * \brief Load USB calibration value from NVM
 */
static void _usb_load_calib(void)
{
#define NVM_USB_PAD_TRANSN_POS 32
#define NVM_USB_PAD_TRANSN_SIZE 5
#define NVM_USB_PAD_TRANSP_POS 37
#define NVM_USB_PAD_TRANSP_SIZE 5
#define NVM_USB_PAD_TRIM_POS 42
#define NVM_USB_PAD_TRIM_SIZE 3
	Usb *    hw = USB;
	uint32_t pad_transn
	    = (*((uint32_t *)(NVMCTRL_SW0) + (NVM_USB_PAD_TRANSN_POS / 32)) >> (NVM_USB_PAD_TRANSN_POS % 32))
	      & ((1 << NVM_USB_PAD_TRANSN_SIZE) - 1);
	uint32_t pad_transp
	    = (*((uint32_t *)(NVMCTRL_SW0) + (NVM_USB_PAD_TRANSP_POS / 32)) >> (NVM_USB_PAD_TRANSP_POS % 32))
	      & ((1 << NVM_USB_PAD_TRANSP_SIZE) - 1);
	uint32_t pad_trim = (*((uint32_t *)(NVMCTRL_SW0) + (NVM_USB_PAD_TRIM_POS / 32)) >> (NVM_USB_PAD_TRIM_POS % 32))
	                    & ((1 << NVM_USB_PAD_TRIM_SIZE) - 1);
	if (pad_transn == 0 || pad_transn == 0x1F) {
		pad_transn = 9;
	}
	if (pad_transp == 0 || pad_transp == 0x1F) {
		pad_transp = 25;
	}
	if (pad_trim == 0 || pad_trim == 0x7) {
		pad_trim = 6;
	}

	hw->DEVICE.PADCAL.reg = USB_PADCAL_TRANSN(pad_transn) | USB_PADCAL_TRANSP(pad_transp) | USB_PADCAL_TRIM(pad_trim);

	hw->DEVICE.QOSCTRL.bit.CQOS = 3;
	hw->DEVICE.QOSCTRL.bit.DQOS = 3;
}

/** \name USB clock source management */
/*@{*/

/** USB clock is generated by DFLL. */
#define USB_CLK_SRC_DFLL 0

/** USB clock is generated by DPLL. */
#define USB_CLK_SRC_DPLL 1

/** Uses DFLL as USB clock source. */
#define CONF_USB_D_CLK_SRC USB_CLK_SRC_DFLL

/** Retry for USB remote wakeup sending. */
#define CONF_USB_RMT_WKUP_RETRY 5

/**
 * \brief Wait DPLL clock to be ready
 */
static inline void _usb_d_dev_wait_dpll_rdy(void)
{
#define DPLL_READY_FLAG (OSCCTRL_DPLLSTATUS_CLKRDY | OSCCTRL_DPLLSTATUS_LOCK)
	while (hri_oscctrl_get_DPLLSTATUS_reg(OSCCTRL, 0, DPLL_READY_FLAG) != DPLL_READY_FLAG)
		;
}

/**
 * \brief Wait DFLL clock to be ready
 */
static inline void _usb_d_dev_wait_dfll_rdy(void)
{
	if (hri_oscctrl_get_DFLLCTRLB_MODE_bit(OSCCTRL)) {
		while (hri_oscctrl_get_STATUS_reg(OSCCTRL, (OSCCTRL_STATUS_DFLLRDY | OSCCTRL_STATUS_DFLLLCKC))
		       != (OSCCTRL_STATUS_DFLLRDY | OSCCTRL_STATUS_DFLLLCKC))
			;
	} else {
		while (hri_oscctrl_get_STATUS_reg(OSCCTRL, OSCCTRL_STATUS_DFLLRDY) != OSCCTRL_STATUS_DFLLRDY)
			;
	}
}

/**
 * \brief Wait USB source clock to be ready
 * \param[in] clk_src Clock source, could be \ref USB_CLK_SRC_DFLL or
 *                    \ref USB_CLK_SRC_DPLL.
 */
static inline void _usb_d_dev_wait_clk_rdy(const uint8_t clk_src)
{
	if (clk_src == USB_CLK_SRC_DFLL) {
		_usb_d_dev_wait_dfll_rdy();
	} else if (clk_src == USB_CLK_SRC_DPLL) {
		_usb_d_dev_wait_dpll_rdy();
	}
}

/*@}*/

/** \name USB general settings */
/*@{*/

/** Increase the value to be aligned. */
#define _usb_align_up(val) (((val)&0x3) ? (((val) + 4 - ((val)&0x3))) : (val))

/** Check if the buffer is in RAM (can DMA), or cache needed
 *  \param[in] a Buffer start address.
 *  \param[in] s Buffer size, in number of bytes.
 *  \return \c true If the buffer is in RAM.
 */
#define _IN_RAM(a, s) ((0x20000000 <= (uint32_t)(a)) && (((uint32_t)(a) + (s)) < 0x20040000))

/** Check if the address should be placed in RAM. */
#define _usb_is_addr4dma(addr, size) _IN_RAM((addr), (size))

/** Check if the address is 32-bit aligned. */
#define _usb_is_aligned(val) (((uint32_t)(val)&0x3) == 0)
/*@}*/

/* Cache static configurations.
 * By default, all OUT endpoint have 64 bytes cache. */
#ifndef CONF_USB_EP0_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP0_CACHE 64
#endif

#ifndef CONF_USB_EP0_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP0_I_CACHE 0
#endif

#ifndef CONF_USB_EP1_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP1_CACHE 64
#endif

#ifndef CONF_USB_EP1_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP1_I_CACHE 0
#endif

#ifndef CONF_USB_EP2_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP2_CACHE 64
#endif

#ifndef CONF_USB_EP2_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP2_I_CACHE 0
#endif

#ifndef CONF_USB_EP3_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP3_CACHE 64
#endif

#ifndef CONF_USB_EP3_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP3_I_CACHE 0
#endif

#ifndef CONF_USB_EP4_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP4_CACHE 64
#endif

#ifndef CONF_USB_EP4_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP4_I_CACHE 0
#endif

#ifndef CONF_USB_EP5_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP5_CACHE 64
#endif

#ifndef CONF_USB_EP5_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP5_I_CACHE 0
#endif

#ifndef CONF_USB_EP6_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP6_CACHE 64
#endif

#ifndef CONF_USB_EP6_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP6_I_CACHE 0
#endif

#ifndef CONF_USB_EP7_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP7_CACHE 64
#endif

#ifndef CONF_USB_EP7_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP7_I_CACHE 0
#endif

#ifndef CONF_USB_EP8_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP8_CACHE 64
#endif

#ifndef CONF_USB_EP8_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP8_I_CACHE 0
#endif

#ifndef CONF_USB_EP9_CACHE
/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#define CONF_USB_EP9_CACHE 64
#endif

#ifndef CONF_USB_EP9_I_CACHE
/** Endpoint cache buffer for IN transactions (none-control). */
#define CONF_USB_EP9_I_CACHE 0
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP0_CACHE
static uint32_t _usb_ep0_cache[_usb_align_up(CONF_USB_EP0_CACHE) / 4];
#else
#define _usb_ep0_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#define _usb_ep0_i_cache NULL

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP1_CACHE && CONF_USB_D_MAX_EP_N >= 1
uint32_t _usb_ep1_cache[_usb_align_up(CONF_USB_EP1_CACHE) / 4];
#else
#define _usb_ep1_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP1_I_CACHE && CONF_USB_D_MAX_EP_N >= 1
uint32_t _usb_ep1_i_cache[_usb_align_up(CONF_USB_EP1_I_CACHE) / 4];
#else
#define _usb_ep1_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP2_CACHE && CONF_USB_D_MAX_EP_N >= 2
static uint32_t _usb_ep2_cache[_usb_align_up(CONF_USB_EP2_CACHE) / 4];
#else
#define _usb_ep2_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP2_I_CACHE && CONF_USB_D_MAX_EP_N >= 2
static uint32_t _usb_ep2_i_cache[_usb_align_up(CONF_USB_EP2_I_CACHE) / 4];
#else
#define _usb_ep2_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP3_CACHE && CONF_USB_D_MAX_EP_N >= 3
static uint32_t _usb_ep3_cache[_usb_align_up(CONF_USB_EP3_CACHE) / 4];
#else
#define _usb_ep3_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP3_I_CACHE && CONF_USB_D_MAX_EP_N >= 3
static uint32_t _usb_ep3_i_cache[_usb_align_up(CONF_USB_EP3_I_CACHE) / 4];
#else
#define _usb_ep3_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP4_CACHE && CONF_USB_D_MAX_EP_N >= 4
static uint32_t _usb_ep4_cache[_usb_align_up(CONF_USB_EP4_CACHE) / 4];
#else
#define _usb_ep4_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP4_I_CACHE && CONF_USB_D_MAX_EP_N >= 4
static uint32_t _usb_ep4_i_cache[_usb_align_up(CONF_USB_EP4_I_CACHE) / 4];
#else
#define _usb_ep4_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP5_CACHE && CONF_USB_D_MAX_EP_N >= 5
static uint32_t _usb_ep5_cache[_usb_align_up(CONF_USB_EP5_CACHE) / 4];
#else
#define _usb_ep5_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP5_I_CACHE && CONF_USB_D_MAX_EP_N >= 5
static uint32_t _usb_ep5_i_cache[_usb_align_up(CONF_USB_EP5_I_CACHE) / 4];
#else
#define _usb_ep5_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP6_CACHE && CONF_USB_D_MAX_EP_N >= 6
static uint32_t _usb_ep6_cache[_usb_align_up(CONF_USB_EP6_CACHE) / 4];
#else
#define _usb_ep6_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP6_I_CACHE && CONF_USB_D_MAX_EP_N >= 6
static uint32_t _usb_ep6_i_cache[_usb_align_up(CONF_USB_EP6_I_CACHE) / 4];
#else
#define _usb_ep6_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP7_CACHE && CONF_USB_D_MAX_EP_N >= 7
static uint32_t _usb_ep7_cache[_usb_align_up(CONF_USB_EP7_CACHE) / 4];
#else
#define _usb_ep7_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP7_I_CACHE && CONF_USB_D_MAX_EP_N >= 7
static uint32_t _usb_ep7_i_cache[_usb_align_up(CONF_USB_EP7_I_CACHE) / 4];
#else
#define _usb_ep7_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP8_CACHE && CONF_USB_D_MAX_EP_N >= 8
static uint32_t _usb_ep8_cache[_usb_align_up(CONF_USB_EP8_CACHE) / 4];
#else
#define _usb_ep8_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP8_I_CACHE && CONF_USB_D_MAX_EP_N >= 8
static uint32_t _usb_ep8_i_cache[_usb_align_up(CONF_USB_EP8_I_CACHE) / 4];
#else
#define _usb_ep8_i_cache NULL
#endif

/** Endpoint cache buffer for OUT transactions (none-control) or SETUP/IN/OUT
 *  transactions (control). */
#if CONF_USB_EP9_CACHE && CONF_USB_D_MAX_EP_N >= 9
static uint32_t _usb_ep9_cache[_usb_align_up(CONF_USB_EP9_CACHE) / 4];
#else
#define _usb_ep9_cache NULL
#endif

/** Endpoint cache buffer for IN transactions (none-control). */
#if CONF_USB_EP9_I_CACHE && CONF_USB_D_MAX_EP_N >= 9
static uint32_t _usb_ep9_i_cache[_usb_align_up(CONF_USB_EP9_I_CACHE) / 4];
#else
#define _usb_ep9_i_cache NULL
#endif

/** Access endpoint cache buffer for OUT transactions (none-control) or
 *  SETUP/IN/OUT transactions (control). */
#define _USB_EP_CACHE(n) ((void *)_usb_ep##n##_cache)

/** Access endpoint cache buffer for IN transactions (none-control). */
#define _USB_EP_I_CACHE(n) ((void *)_usb_ep##n##_i_cache)

/** The configuration settings for one of the endpoint hardware. */
struct _usb_ep_cfg_item {
	/* Endpoint cache buffer for OUT transactions (none-control) or
	 * SETUP/IN/OUT transactions (control). */
	void *cache;
	/* endpoint cache buffer for IN transactions (none-control). */
	void *i_cache;
	/* Cache buffer size for OUT transactions (none-control) or
	 * SETUP/IN/OUT transactions (control). */
	uint16_t size;
	/* Cache buffer size for IN transactions (none-control). */
	uint16_t i_size;
};

/** Build the endpoint configuration settings for one endpoint. */
#define _USB_EP_CFG_ITEM(n)                                                                                            \
	{                                                                                                                  \
		_USB_EP_CACHE(n), _USB_EP_I_CACHE(n), CONF_USB_EP##n##_CACHE, CONF_USB_EP##n##_I_CACHE,                        \
	}

/** The configuration settings for all endpoint. */
static const struct _usb_ep_cfg_item _usb_ep_cfgs[] = {_USB_EP_CFG_ITEM(0)
#if CONF_USB_D_MAX_EP_N >= 1
                                                           ,
                                                       _USB_EP_CFG_ITEM(1)
#endif
#if CONF_USB_D_MAX_EP_N >= 2
                                                           ,
                                                       _USB_EP_CFG_ITEM(2)
#endif
#if CONF_USB_D_MAX_EP_N >= 3
                                                           ,
                                                       _USB_EP_CFG_ITEM(3)
#endif
#if CONF_USB_D_MAX_EP_N >= 4
                                                           ,
                                                       _USB_EP_CFG_ITEM(4)
#endif
#if CONF_USB_D_MAX_EP_N >= 5
                                                           ,
                                                       _USB_EP_CFG_ITEM(5)
#endif
#if CONF_USB_D_MAX_EP_N >= 6
                                                           ,
                                                       _USB_EP_CFG_ITEM(6)
#endif
#if CONF_USB_D_MAX_EP_N >= 7
                                                           ,
                                                       _USB_EP_CFG_ITEM(7)
#endif
#if CONF_USB_D_MAX_EP_N >= 8
                                                           ,
                                                       _USB_EP_CFG_ITEM(8)
#endif
#if CONF_USB_D_MAX_EP_N >= 9
                                                           ,
                                                       _USB_EP_CFG_ITEM(9)
#endif
};

/** \name HW specific settings and implements */
/*@{*/

/** Number of endpoints supported. */
#define USB_D_N_EP (1 + CONF_USB_D_NUM_EP_SP * 2)

/** HPL USB device endpoint struct. */
struct _usb_d_dev_ep {
	/** Pointer to transaction buffer. */
	uint8_t *trans_buf;
	/** Transaction size. */
	uint32_t trans_size;
	/** Transaction transferred count. */
	uint32_t trans_count;

	/** Pointer to cache buffer, must be aligned. */
	uint8_t *cache;

	/** Endpoint size. */
	uint16_t size;
	/** Endpoint address. */
	uint8_t ep;
	/** Feature flags. */
	union {
		/** Interpreted by bit fields. */
		struct {
			/** EPCFG.ETYPE. */
			uint8_t eptype : 3;
			/** Stall status. */
			uint8_t is_stalled : 1;
			/** Transaction auto ZLP. */
			uint8_t need_zlp : 1;
			/** Transaction with cache */
			uint8_t use_cache : 1;
			/** Endpoint is busy. */
			uint8_t is_busy : 1;
			/** Transaction direction. */
			uint8_t dir : 1;
		} bits;
		uint8_t u8;
	} flags;
};

/** Check if the endpoint is used. */
#define _usb_d_dev_ep_is_used(ept) ((ept)->ep != 0xFF)

/** Check if the endpoint is busy doing transactions. */
#define _usb_d_dev_ep_is_busy(ept) ((ept)->flags.bits.is_busy)

/** Check if the endpoint is control endpoint. */
#define _usb_d_dev_ep_is_ctrl(ept) ((ept)->flags.bits.eptype == USB_D_EPTYPE_CTRL)

/** Check if the endpoint transactions are IN. */
#define _usb_d_dev_ep_is_in(ept) ((ept)->flags.bits.dir)

/** Interrupt flags for SETUP transaction. */
#define USB_D_SETUP_INT_FLAGS (USB_DEVICE_EPINTFLAG_RXSTP)

/** Interrupt flags for BANK1 transactions. */
#define USB_D_BANK1_INT_FLAGS (USB_DEVICE_EPINTFLAG_TRCPT1 | USB_DEVICE_EPINTFLAG_TRFAIL1 | USB_DEVICE_EPINTFLAG_STALL1)

/** Interrupt flags for BANK0 transactions. */
#define USB_D_BANK0_INT_FLAGS (USB_DEVICE_EPINTFLAG_TRCPT0 | USB_DEVICE_EPINTFLAG_TRFAIL0 | USB_DEVICE_EPINTFLAG_STALL0)

/** Interrupt flags for SETUP/IN/OUT transactions. */
#define USB_D_ALL_INT_FLAGS (0x7F)

/** Interrupt flags for WAKEUP event. */
#define USB_D_WAKEUP_INT_FLAGS (USB_DEVICE_INTFLAG_UPRSM | USB_DEVICE_INTFLAG_EORSM | USB_DEVICE_INTFLAG_WAKEUP)

/** Interrupt flags for SUSPEND event. */
#define USB_D_SUSPEND_INT_FLAGS (USB_DEVICE_INTFLAG_LPMSUSP | USB_DEVICE_INTFLAG_SUSPEND)

/** Max data bytes for a single DMA transfer. */
#define USB_D_DEV_TRANS_MAX 8192 /* 14-bits, uses 13-bits. */

/** Endpoint type setting to disable. */
#define USB_D_EPTYPE_DISABLE 0

/** Endpoint type setting to work as control endpoint. */
#define USB_D_EPTYPE_CTRL 1

/** Endpoint type setting to work as isochronous endpoint. */
#define USB_D_EPTYPE_ISOCH 2

/** Endpoint type setting to work as interrupt endpoint. */
#define USB_D_EPTYPE_INT 3

/** Endpoint type setting to work as bulk endpoint. */
#define USB_D_EPTYPE_BULK 4

/** Endpoint type setting for dual bank endpoint. */
#define USB_D_EPTYPE_DUAL 5

/** EPCFG register value for control endpoints. */
#define USB_D_EPCFG_CTRL 0x11

/** HPL USB device struct. */
struct _usb_d_dev {
	/** Callbacks of USB device. */
	struct _usb_d_dev_callbacks callbacks;
	/** Endpoint transaction callbacks. */
	struct _usb_d_dev_ep_callbacks ep_callbacks;
	/** Endpoints (ep0 + others). */
	struct _usb_d_dev_ep ep[USB_D_N_EP];
};

/** Private data for SAM0 USB peripheral.
 */
typedef struct _usb_d_dev_prvt {
	/** USB device descriptor table for peripheral to work. */
	UsbDeviceDescriptor desc_table[CONF_USB_D_MAX_EP_N + 1];
} usb_d_dev_prvt_t;

/*@}*/

/** USB device driver instance. */
static struct _usb_d_dev dev_inst;

/** USB device driver private data instance. */
static struct _usb_d_dev_prvt prvt_inst;

static void _usb_d_dev_reset_epts(void);

static void _usb_d_dev_trans_done(struct _usb_d_dev_ep *ept, const int32_t status);
static void _usb_d_dev_trans_stop(struct _usb_d_dev_ep *ept, bool dir, const int32_t code);

static void _usb_d_dev_in_next(struct _usb_d_dev_ep *ept, bool isr);
static void _usb_d_dev_out_next(struct _usb_d_dev_ep *ept, bool isr);

static inline void _usb_d_dev_trans_setup(struct _usb_d_dev_ep *ept);

/** \brief ACK the endpoint interrupt
 * \param[in] epn Endpoint number.
 * \param[in] flags Interrupt flags.
 */
static inline void _usbd_ep_int_ack(uint8_t epn, uint32_t flags)
{
	hri_usbendpoint_clear_EPINTFLAG_reg(USB, epn, flags);
}

/** \brief Enable the endpoint interrupt
 * \param[in] epn Endpoint number.
 * \param[in] flags Interrupt flags.
 */
static inline void _usbd_ep_int_en(uint8_t epn, uint32_t flags)
{
	hri_usbendpoint_set_EPINTEN_reg(USB, epn, flags);
}

/** \brief Disable the endpoint interrupt
 * \param[in] epn Endpoint number.
 * \param[in] flags Interrupt flags.
 */
static inline void _usbd_ep_int_dis(uint8_t epn, uint32_t flags)
{
	hri_usbendpoint_clear_EPINTEN_reg(USB, epn, flags);
}

/** \brief Check if endpoint is control endpoint
 * \param[in] epn Endpoint number.
 */
static inline bool _usbd_ep_is_ctrl(uint8_t epn)
{
	return (hri_usbendpoint_read_EPCFG_reg(USB, epn) == USB_D_EPCFG_CTRL);
}

/** \brief Set endpoint stall
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] st Stall status.
 */
static inline void _usbd_ep_set_stall(uint8_t epn, uint8_t bank_n, bool st)
{
	if (st) {
		hri_usbendpoint_set_EPSTATUS_reg(USB, epn, (USB_DEVICE_EPSTATUS_STALLRQ0 << bank_n));
	} else {
		hri_usbendpoint_clear_EPSTATUS_reg(USB, epn, (USB_DEVICE_EPSTATUS_STALLRQ0 << bank_n));
	}
}

/** \brief Check if the endpoint is stalled
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \return \c true if it's stalled.
 */
static inline bool _usbd_ep_is_stalled(uint8_t epn, uint8_t bank_n)
{
	Usb *hw = USB;
	return (hri_usbendpoint_read_EPSTATUS_reg(hw, epn) & (USB_DEVICE_EPSTATUS_STALLRQ0 << bank_n));
}

/** \brief Check if stall has been sent from the endpoint
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \return \c true if it's sent.
 */
static inline bool _usbd_ep_is_stall_sent(uint8_t epn, uint8_t bank_n)
{
	Usb *hw = USB;
	return (hri_usbendpoint_read_EPINTFLAG_reg(hw, epn) & (USB_DEVICE_EPINTFLAG_STALL0 << bank_n));
}

/** \brief ACK endpoint STALL interrupt
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 */
static inline void _usbd_ep_ack_stall(uint8_t epn, uint8_t bank_n)
{
	_usbd_ep_int_ack(epn, (USB_DEVICE_EPINTFLAG_STALL0 << bank_n));
}

/** \brief Enable/disable endpoint STALL interrupt
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] en \c true to enable, \c false to disable.
 */
static inline void _usbd_ep_int_stall_en(uint8_t epn, uint8_t bank_n, const bool en)
{
	if (en) {
		_usbd_ep_int_en(epn, USB_DEVICE_EPINTFLAG_STALL0 << bank_n);
	} else {
		_usbd_ep_int_dis(epn, USB_DEVICE_EPINTFLAG_STALL0 << bank_n);
	}
}

/** \brief Stop SETUP transactions
 * \param[in] epn Endpoint number.
 */
static inline void _usbd_ep_stop_setup(uint8_t epn)
{
	hri_usbendpoint_clear_EPINTEN_RXSTP_bit(USB, epn);
}

/** \brief Check if SETUP packet is ready in cache
 * \param[in] epn Endpoint number.
 */
static inline bool _usbd_ep_is_setup(uint8_t epn)
{
	return hri_usbendpoint_get_EPINTFLAG_reg(USB, epn, USB_DEVICE_EPINTFLAG_RXSTP);
}

/** \brief ACK endpoint SETUP interrupt
 * \param[in] epn Endpoint number.
 */
static inline void _usbd_ep_ack_setup(uint8_t epn)
{
	_usbd_ep_int_ack(epn, USB_DEVICE_EPINTFLAG_RXSTP);
}

/** \brief Set endpoint toggle value
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] tgl Toggle value.
 */
static inline void _usbd_ep_set_toggle(uint8_t epn, uint8_t bank_n, uint8_t tgl)
{
	if (tgl) {
		hri_usbendpoint_set_EPSTATUS_reg(USB, epn, (USB_DEVICE_EPSTATUS_DTGLOUT << bank_n));
	} else {
		hri_usbendpoint_clear_EPSTATUS_reg(USB, epn, (USB_DEVICE_EPSTATUS_DTGLOUT << bank_n));
	}
}

/** \brief ACK IN/OUT complete interrupt
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 */
static inline void _usbd_ep_ack_io_cpt(uint8_t epn, uint8_t bank_n)
{
	_usbd_ep_int_ack(epn, USB_DEVICE_EPINTFLAG_TRCPT0 << bank_n);
}

/** \brief Set DMA buffer used for bank data
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] addr DMA buffer address to set.
 */
static inline void _usbd_ep_set_buf(uint8_t epn, uint8_t bank_n, uint32_t addr)
{
	UsbDeviceDescBank *bank = &prvt_inst.desc_table[epn].DeviceDescBank[bank_n];
	bank->ADDR.reg          = addr;
}

/** \brief Set bank count for IN transactions
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] count Data count for IN.
 */
static inline void _usbd_ep_set_in_count(uint8_t epn, uint8_t bank_n, uint16_t count)
{
	UsbDeviceDescBank *bank             = &prvt_inst.desc_table[epn].DeviceDescBank[bank_n];
	bank->PCKSIZE.bit.MULTI_PACKET_SIZE = count;
}

/** \brief Set bank size for IN transactions
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] size Data size for IN.
 */
static inline void _usbd_ep_set_in_size(uint8_t epn, uint8_t bank_n, uint16_t size)
{
	UsbDeviceDescBank *bank      = &prvt_inst.desc_table[epn].DeviceDescBank[bank_n];
	bank->PCKSIZE.bit.BYTE_COUNT = size;
}

/** \brief Set bank count for OUT transaction
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] count Data count for OUT.
 */
static inline void _usbd_ep_set_out_count(uint8_t epn, uint8_t bank_n, uint16_t count)
{
	UsbDeviceDescBank *bank      = &prvt_inst.desc_table[epn].DeviceDescBank[bank_n];
	bank->PCKSIZE.bit.BYTE_COUNT = count;
}

/** \brief Set bank size for OUT transactions
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] size Data size for OUT.
 */
static inline void _usbd_ep_set_out_size(uint8_t epn, uint8_t bank_n, uint16_t size)
{
	UsbDeviceDescBank *bank             = &prvt_inst.desc_table[epn].DeviceDescBank[bank_n];
	bank->PCKSIZE.bit.MULTI_PACKET_SIZE = size;
}

/** Set bank size and count for IN transactions
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] size Data size.
 * \param[in] count Initial data count.
 */
static inline void _usbd_ep_set_in_trans(uint8_t epn, uint8_t bank_n, uint32_t size, uint32_t count)
{
	_usbd_ep_set_in_size(epn, bank_n, size);
	_usbd_ep_set_in_count(epn, bank_n, count);
}

/** \brief Set bank size and count for OUT transaction
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] size Data size.
 * \param[in] count Initial data count.
 */
static inline void _usbd_ep_set_out_trans(uint8_t epn, uint8_t bank_n, uint32_t size, uint32_t count)
{
	_usbd_ep_set_out_size(epn, bank_n, size);
	_usbd_ep_set_out_count(epn, bank_n, count);
}

/** \brief Clear bank status
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 */
static inline void _usbd_ep_clear_bank_status(uint8_t epn, uint8_t bank_n)
{
	UsbDeviceDescBank *bank = &prvt_inst.desc_table[epn].DeviceDescBank[bank_n];
	bank->STATUS_BK.reg     = 0;
}

/** Set IN ready for IN transactions
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] rdy Set to \c true to indicate IN packet ready to TX.
 */
static inline void _usbd_ep_set_in_rdy(uint8_t epn, uint8_t bank_n, const bool rdy)
{
	if (rdy) {
		hri_usbendpoint_set_EPSTATUS_reg(USB, epn, USB_DEVICE_EPSTATUS_BK0RDY << bank_n);
	} else {
		hri_usbendpoint_clear_EPSTATUS_reg(USB, epn, USB_DEVICE_EPSTATUS_BK0RDY << bank_n);
	}
}

/** \brief Set bank ready for OUT transactions
 * \param[in] epn Endpoint number.
 * \param[in] bank_n Endpoint bank number.
 * \param[in] rdy Set to \c true to indicate OUT bank ready to RX.
 */
static inline void _usbd_ep_set_out_rdy(uint8_t epn, uint8_t bank_n, const bool rdy)
{
	if (rdy) {
		hri_usbendpoint_clear_EPSTATUS_reg(USB, epn, USB_DEVICE_EPSTATUS_BK0RDY << bank_n);
	} else {
		hri_usbendpoint_set_EPSTATUS_reg(USB, epn, USB_DEVICE_EPSTATUS_BK0RDY << bank_n);
	}
}

/**
 *  \brief Convert USB endpoint size to HW PCKSIZE.SIZE
 * \param[in] n Number of bytes of endpoint size.
 */
static inline uint8_t _usbd_ep_pcksize_size(uint16_t n)
{
	return (
	    (n > 512)
	        ? 7
	        : ((n > 256) ? 6 : ((n > 128) ? 5 : ((n > 64) ? 4 : ((n > 32) ? 3 : ((n > 16) ? 2 : ((n > 8) ? 1 : 0)))))));
}

/**
 *  \brief Obtain endpoint descriptor pointer
 * \param[in] epn Endpoint number.
 * \param[in] dir Endpoint direction.
 */
static inline struct _usb_d_dev_ep *_usb_d_dev_ept(uint8_t epn, bool dir)
{
	uint8_t ep_index = (epn == 0) ? 0 : (dir ? (epn + CONF_USB_D_MAX_EP_N) : epn);
	return &dev_inst.ep[ep_index];
}

/**
 * \brief Handles USB SOF interrupt
 */
static inline void _usb_d_dev_sof(void)
{
	/* ACK SOF interrupt. */
	hri_usbdevice_clear_INTFLAG_reg(USB, USB_DEVICE_INTFLAG_SOF);
	dev_inst.callbacks.sof();
}

/**
 * \brief Handles USB LPM Suspend interrupt
 */
static inline void _usb_d_dev_lpmsusp(void)
{
	uint8_t  i;
	uint32_t lpm_variable = 0;

	/* ACK LPMSUSP interrupt. */
	hri_usbdevice_clear_INTFLAG_reg(USB, USB_D_SUSPEND_INT_FLAGS);
	/* Change interrupt masks */
	hri_usbdevice_clear_INTEN_reg(USB, USB_D_SUSPEND_INT_FLAGS);
	hri_usbdevice_set_INTEN_reg(USB, USB_D_WAKEUP_INT_FLAGS);

	/* Find LPM data */
	for (i = 0; i < CONF_USB_D_MAX_EP_N; i++) {
		UsbDeviceDescBank *bank = &prvt_inst.desc_table[i].DeviceDescBank[0];
		if (bank->EXTREG.bit.SUBPID == 0x3) {
			/* Save LPM variable */
			lpm_variable = bank->EXTREG.bit.VARIABLE;
			/* Clear */
			bank->EXTREG.reg = 0;
			break;
		}
	}
	dev_inst.callbacks.event(USB_EV_LPM_SUSPEND, lpm_variable);
}

/**
 * \brief Handles USB RAM Error interrupt
 */
static inline void _usb_d_dev_ramerr(void)
{
	hri_usbdevice_clear_INTFLAG_reg(USB, USB_DEVICE_INTFLAG_RAMACER);
	dev_inst.callbacks.event(USB_EV_ERROR, 0);
}

/**
 * \brief Handles USB resume/wakeup interrupts
 */
static inline void _usb_d_dev_wakeup(void)
{
	hri_usbdevice_clear_INTFLAG_reg(USB, USB_D_WAKEUP_INT_FLAGS);
	hri_usbdevice_clear_INTEN_reg(USB, USB_D_WAKEUP_INT_FLAGS);
	hri_usbdevice_set_INTEN_reg(USB, USB_D_SUSPEND_INT_FLAGS);

	_usb_d_dev_wait_clk_rdy(CONF_USB_D_CLK_SRC);
	dev_inst.callbacks.event(USB_EV_WAKEUP, 0);
}

/**
 * \brief Handles USB signal reset interrupt
 */
static inline void _usb_d_dev_reset(void)
{
	/* EP0 will not be reseted by USB RESET, disable manually. */
	hri_usbendpoint_write_EPCFG_reg(USB, 0, 0);

	hri_usbdevice_clear_INTFLAG_reg(USB, USB_DEVICE_INTFLAG_EORST);
	hri_usbdevice_clear_INTEN_reg(USB, USB_D_WAKEUP_INT_FLAGS);
	hri_usbdevice_set_INTEN_reg(USB, USB_D_SUSPEND_INT_FLAGS);

	_usb_d_dev_reset_epts();
	dev_inst.callbacks.event(USB_EV_RESET, 0);
}

static inline void _usb_d_dev_suspend(void)
{
	hri_usbdevice_clear_INTFLAG_reg(USB, USB_D_SUSPEND_INT_FLAGS);
	hri_usbdevice_clear_INTEN_reg(USB, USB_D_SUSPEND_INT_FLAGS);
	hri_usbdevice_set_INTEN_reg(USB, USB_D_WAKEUP_INT_FLAGS);

	dev_inst.callbacks.event(USB_EV_SUSPEND, 0);
}

/**
 * \brief Handles USB non-endpoint interrupt
 */
static inline bool _usb_d_dev_handle_nep(void)
{
	bool     rc    = true;
	uint16_t flags = hri_usbdevice_read_INTFLAG_reg(USB);
	flags &= hri_usbdevice_read_INTEN_reg(USB);

	if (flags & USB_DEVICE_INTFLAG_SOF) {
		_usb_d_dev_sof();
		return true;
	}
	if (flags & USB_DEVICE_INTFLAG_LPMSUSP) {
		_usb_d_dev_lpmsusp();
	} else if (flags & USB_DEVICE_INTFLAG_RAMACER) {
		_usb_d_dev_ramerr();
	} else if (flags & USB_D_WAKEUP_INT_FLAGS) {
		_usb_d_dev_wakeup();
	} else if (flags & USB_DEVICE_INTFLAG_EORST) {
		_usb_d_dev_reset();
	} else if (flags & USB_DEVICE_INTFLAG_SUSPEND) {
		_usb_d_dev_suspend();
	} else {
		rc = false;
	}
	return rc;
}

/**
 * \brief Prepare next IN transactions
 * \param[in] ept Pointer to endpoint information.
 * \param[in] isr Invoked from ISR.
 */
static void _usb_d_dev_in_next(struct _usb_d_dev_ep *ept, bool isr)
{
	Usb *              hw          = USB;
	uint8_t            epn         = USB_EP_GET_N(ept->ep);
	UsbDeviceDescBank *bank        = &prvt_inst.desc_table[epn].DeviceDescBank[0];
	uint16_t           trans_count = isr ? bank[1].PCKSIZE.bit.BYTE_COUNT : 0;
	uint16_t           trans_next;
	uint16_t           last_pkt = trans_count & ((ept->size == 1023) ? ept->size : (ept->size - 1));
	uint8_t            inten    = 0;
	bool               is_ctrl  = _usb_d_dev_ep_is_ctrl(ept);

	if (isr) {
		_usbd_ep_ack_io_cpt(epn, 1);
	}

	ept->trans_count += trans_count;
	/* Send more data. */
	if (ept->trans_count < ept->trans_size) {
		trans_next = ept->trans_size - ept->trans_count;
		if (ept->flags.bits.use_cache) {
			if (trans_next > ept->size) {
				trans_next = ept->size;
			}
			memcpy(ept->cache, &ept->trans_buf[ept->trans_count], trans_next);
			_usbd_ep_set_buf(epn, 1, (uint32_t)ept->cache);
		} else {
			if (trans_next > USB_D_DEV_TRANS_MAX) {
				trans_next = USB_D_DEV_TRANS_MAX;
			}
			_usbd_ep_set_buf(epn, 1, (uint32_t)&ept->trans_buf[ept->trans_count]);
		}
		_usbd_ep_set_in_trans(epn, 1, trans_next, 0);
		goto _in_tx_exec;
	} else if (ept->flags.bits.need_zlp) {
		ept->flags.bits.need_zlp = 0;
		_usbd_ep_set_in_trans(epn, 1, 0, 0);
		goto _in_tx_exec;
	}
	/* Complete. */
	if (is_ctrl) {
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, USB_D_BANK1_INT_FLAGS | USB_DEVICE_EPINTFLAG_TRCPT0);
	} else {
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, USB_D_BANK1_INT_FLAGS);
	}

	/* No ping-pong, so ask more data without background transfer. */
	if (last_pkt == ept->size) {
		ept->flags.bits.is_busy = 0;
		if (dev_inst.ep_callbacks.more(ept->ep, ept->trans_count)) {
			/* More data added. */
			return;
		}
		ept->flags.bits.is_busy = 1;
	}
	/* Finish normally. */
	_usb_d_dev_trans_done(ept, USB_TRANS_DONE);
	return;

_in_tx_exec:
	if (!isr) {
		if (is_ctrl) {
			/* Control endpoint: SETUP or OUT will abort IN transaction.
			 * SETUP: terminate the IN without any notification. Trigger
			 *        SETUP callback.
			 * OUT NAK: terminate IN.
			 */
			inten = USB_D_BANK1_INT_FLAGS | USB_DEVICE_EPINTFLAG_TRFAIL0;
		} else {
			/* Initialize normal IN transaction. */
			inten = USB_D_BANK1_INT_FLAGS;
		}
		hri_usbendpoint_set_EPINTEN_reg(hw, epn, inten);
	}
	_usbd_ep_set_in_rdy(epn, 1, true);
}

/**
 * \brief Prepare next OUT transactions
 * \param[in] ept Pointer to endpoint information.
 * \param[in] isr Invoked from ISR.
 */
static void _usb_d_dev_out_next(struct _usb_d_dev_ep *ept, bool isr)
{
	Usb *              hw         = USB;
	uint8_t            epn        = USB_EP_GET_N(ept->ep);
	UsbDeviceDescBank *bank       = &prvt_inst.desc_table[epn].DeviceDescBank[0];
	uint16_t           trans_size = isr ? bank->PCKSIZE.bit.MULTI_PACKET_SIZE : 0;
	uint16_t           last_trans = isr ? bank->PCKSIZE.bit.BYTE_COUNT : 0;
	uint16_t           size_mask  = (ept->size == 1023) ? 1023 : (ept->size - 1);
	uint16_t           last_pkt   = last_trans & size_mask;
	uint16_t           trans_next;
	uint8_t            inten;
	bool               is_ctrl = _usb_d_dev_ep_is_ctrl(ept);

	if (isr) {
		_usbd_ep_ack_io_cpt(epn, 0);
	}

	/* If cache is used, copy data to buffer. */
	if (ept->flags.bits.use_cache && ept->trans_size) {
		uint16_t buf_remain = ept->trans_size - ept->trans_count;
		memcpy(&ept->trans_buf[ept->trans_count], ept->cache, (buf_remain > last_pkt) ? last_pkt : buf_remain);
	}

	/* Force wait ZLP */
	if (ept->trans_size == 0 && ept->flags.bits.need_zlp) {
		ept->flags.bits.need_zlp  = 0;
		ept->flags.bits.use_cache = 1;
		_usbd_ep_set_buf(epn, 0, (uint32_t)ept->cache);
		_usbd_ep_set_out_trans(epn, 0, ept->size, 0);
		goto _out_rx_exec;
	} else if (isr && last_pkt < ept->size) {
		/* Short packet. */
		ept->flags.bits.need_zlp = 0;
		ept->trans_count += last_trans;
	} else {
		/* Full packets. */
		ept->trans_count += trans_size;

		/* Wait more data */
		if (ept->trans_count < ept->trans_size) {
			/* Continue OUT */
			trans_next = ept->trans_size - ept->trans_count;
			if (ept->flags.bits.use_cache) {
				/* Expect single packet each time. */
				if (trans_next > ept->size) {
					trans_next = ept->size;
				}
				_usbd_ep_set_buf(epn, 0, (uint32_t)ept->cache);
			} else {
				/* Multiple packets each time. */
				if (trans_next > ept->size) {
					if (trans_next > USB_D_DEV_TRANS_MAX) {
						trans_next = USB_D_DEV_TRANS_MAX;
					} else {
						/* Must expect multiple of ep size. */
						trans_next -= trans_next & size_mask;
					}
				} else if (trans_next < ept->size) {
					/* Last un-aligned packet should be cached. */
					ept->flags.bits.use_cache = 1;
				}
				_usbd_ep_set_buf(epn, 0, (uint32_t)&ept->trans_buf[ept->trans_count]);
			}
			_usbd_ep_set_out_trans(epn, 0, trans_next, 0);
			goto _out_rx_exec;
		}
	}
	/* Finish normally. */
	if (is_ctrl) {
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, USB_D_BANK0_INT_FLAGS | USB_DEVICE_EPINTFLAG_TRFAIL1);
	} else {
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, USB_D_BANK0_INT_FLAGS);
	}
	/* Use ep0 out cache for next setup packets */
	if (0 == epn) {
		_usbd_ep_set_buf(epn, 0, (uint32_t)ept->cache);
	}
	_usb_d_dev_trans_done(ept, USB_TRANS_DONE);
	return;

_out_rx_exec:
	if (!isr) {
		if (is_ctrl) {
			/* Initialize control OUT transaction. */

			/* Control transfer: SETUP or IN request will abort the
			 *                   OUT transactions.
			 * SETUP: terminate OUT without any notification.
			 *        Trigger SETUP notification.
			 * IN NAK: finish OUT normally. Notify data done.
			 */
			_usbd_ep_clear_bank_status(epn, 1);
			/* Detect OUT, SETUP, NAK IN */
			inten = USB_D_BANK0_INT_FLAGS | USB_DEVICE_EPINTFLAG_TRFAIL1;
		} else {
			/* Initialize normal OUT transaction. */
			inten = USB_D_BANK0_INT_FLAGS;
		}
		hri_usbendpoint_set_EPINTEN_reg(hw, epn, inten);
	}
	_usbd_ep_set_out_rdy(epn, 0, true);
}

/**
 * \brief Handles setup received interrupt
 * \param[in] ept Pointer to endpoint information.
 */
static void _usb_d_dev_handle_setup(struct _usb_d_dev_ep *ept)
{
	uint8_t epn     = USB_EP_GET_N(ept->ep);
	bool    is_ctrl = _usb_d_dev_ep_is_ctrl(ept);

	if (!is_ctrl) {
		/* Should never be here! */
		_usbd_ep_ack_setup(epn);
		_usbd_ep_stop_setup(epn);
		return;
	}
	/* Control transfer:
	 * SETUP transaction will terminate IN/OUT transaction,
	 * and start new transaction with received SETUP packet.
	 */
	if (_usb_d_dev_ep_is_busy(ept)) {
		ept->flags.bits.is_busy = 0;

		/* Stop transfer on either direction. */
		_usbd_ep_set_in_rdy(epn, 1, false);
		_usbd_ep_set_out_rdy(epn, 0, false);
	}
	ept->flags.bits.is_stalled = 0;

	/* Clear status and notify SETUP */
	_usbd_ep_clear_bank_status(epn, 0);
	_usbd_ep_clear_bank_status(epn, 1);
	_usbd_ep_int_ack(epn, USB_D_BANK0_INT_FLAGS | USB_D_BANK1_INT_FLAGS);
	_usbd_ep_int_dis(epn, USB_D_BANK0_INT_FLAGS | USB_D_BANK1_INT_FLAGS);
	/* Invoke callback. */
	dev_inst.ep_callbacks.setup(ept->ep);
}

/**
 * \brief Handles stall sent interrupt
 * \param[in] ept Pointer to endpoint information.
 * \param[in] bank_n Bank number.
 */
static void _usb_d_dev_handle_stall(struct _usb_d_dev_ep *ept, const uint8_t bank_n)
{
	uint8_t epn = USB_EP_GET_N(ept->ep);
	/* Clear interrupt enable. Leave status there for status check. */
	_usbd_ep_int_stall_en(epn, bank_n, false);
	dev_inst.ep_callbacks.done(ept->ep, USB_TRANS_STALL, ept->trans_count);
}

/**
 * \brief Handles transaction fail interrupt
 * \param[in] ept Pointer to endpoint information.
 * \param[in] bank_n Bank number.
 */
static void _usb_d_dev_handle_trfail(struct _usb_d_dev_ep *ept, const uint8_t bank_n)
{
	Usb *              hw      = USB;
	uint8_t            epn     = USB_EP_GET_N(ept->ep);
	const uint8_t      fail[2] = {USB_DEVICE_EPINTFLAG_TRFAIL0, USB_DEVICE_EPINTFLAG_TRFAIL1};
	UsbDeviceDescBank *bank    = prvt_inst.desc_table[epn].DeviceDescBank;
	uint8_t            eptype
	    = bank_n ? hri_usbendpoint_read_EPCFG_EPTYPE1_bf(hw, epn) : hri_usbendpoint_read_EPCFG_EPTYPE0_bf(hw, epn);
	bool                      is_ctrl = _usb_d_dev_ep_is_ctrl(ept);
	USB_DEVICE_STATUS_BK_Type st;
	st.reg = bank[bank_n].STATUS_BK.reg;

	if ((eptype == USB_D_EPTYPE_ISOCH) && st.bit.CRCERR) {
		bank[bank_n].STATUS_BK.bit.CRCERR = 0;
		hri_usbendpoint_clear_EPINTFLAG_reg(hw, epn, fail[bank_n]);
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, fail[bank_n]);
		_usb_d_dev_trans_stop(ept, bank_n, USB_TRANS_ERROR);
	} else if (st.bit.ERRORFLOW) {
		bank[bank_n].STATUS_BK.bit.ERRORFLOW = 0;
		hri_usbendpoint_clear_EPINTFLAG_reg(hw, epn, fail[bank_n]);
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, fail[bank_n]);
		/* Abort control transfer. */
		if (is_ctrl && _usb_d_dev_ep_is_busy(ept)) {
			if (bank_n != _usb_d_dev_ep_is_in(ept)) {
				_usb_d_dev_trans_stop(ept, _usb_d_dev_ep_is_in(ept), USB_TRANS_DONE);
			}
		}
	} else {
		_usbd_ep_clear_bank_status(epn, bank_n);
		hri_usbendpoint_clear_EPINTFLAG_reg(hw, epn, fail[bank_n]);
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, fail[bank_n]);
	}
}

/**
 * \brief Analyze flags for setup transaction
 * \param[in] ept Pointer to endpoint information.
 * \param[in] flags Endpoint interrupt flags.
 */
static inline void _usb_d_dev_trans_setup_isr(struct _usb_d_dev_ep *ept, const uint8_t flags)
{
	/*
	 * SETPU is automatically ACKed by hardware
	 * OUT & IN should be set to NAK when checking SETUP
	 * No need to check OUT & IN status.
	 */
	if (flags & USB_DEVICE_EPINTFLAG_RXSTP) {
		_usb_d_dev_handle_setup(ept);
	} else if (flags & USB_DEVICE_EPINTFLAG_STALL1) {
		_usb_d_dev_handle_stall(ept, 1);
	} else if (flags & USB_DEVICE_EPINTFLAG_STALL0) {
		_usb_d_dev_handle_stall(ept, 0);
	}
}

/**
 * \brief Analyze flags for IN transactions
 * \param[in] ept Pointer to endpoint information.
 * \param[in] flags Endpoint interrupt flags.
 */
static inline void _usb_d_dev_trans_in_isr(struct _usb_d_dev_ep *ept, const uint8_t flags)
{
	/*
	 * Check IN flags
	 * If control endpoint, SETUP & OUT is checked to see if abort
	 */
	if (flags & USB_DEVICE_EPINTFLAG_STALL1) {
		_usb_d_dev_handle_stall(ept, 1);
	} else if (flags & USB_DEVICE_EPINTFLAG_TRFAIL1) {
		_usb_d_dev_handle_trfail(ept, 1);
	} else if (flags & USB_DEVICE_EPINTFLAG_TRCPT1) {
		_usb_d_dev_in_next(ept, true);
	} else if (_usb_d_dev_ep_is_ctrl(ept)) {
		/* Check OUT NAK
		 * Check SETUP
		 */
		if (flags & USB_DEVICE_EPINTFLAG_TRFAIL0) {
			_usb_d_dev_handle_trfail(ept, 0);
		} else if (flags & USB_DEVICE_EPINTFLAG_RXSTP) {
			_usb_d_dev_handle_setup(ept);
		}
	}
}

/**
 * \brief Analyze flags for OUT transactions
 * \param[in] ept Pointer to endpoint information.
 * \param[in] flags Endpoint interrupt flags.
 */
static inline void _usb_d_dev_trans_out_isr(struct _usb_d_dev_ep *ept, const uint8_t flags)
{
	/*
	 * Check OUT flags.
	 * If control endpoint, SETUP & IN NAK is checked to see if abort
	 */
	if (flags & USB_DEVICE_EPINTFLAG_STALL0) {
		_usb_d_dev_handle_stall(ept, 0);
	} else if (flags & USB_DEVICE_EPINTFLAG_TRFAIL0) {
		_usb_d_dev_handle_trfail(ept, 0);
	} else if (flags & USB_DEVICE_EPINTFLAG_TRCPT0) {
		_usb_d_dev_out_next(ept, true);
	} else if (_usb_d_dev_ep_is_ctrl(ept)) {
		/* Check IN NAK
		 * Check SETUP
		 */
		if (flags & USB_DEVICE_EPINTFLAG_TRFAIL1) {
			_usb_d_dev_handle_trfail(ept, 1);
		} else if (flags & USB_DEVICE_EPINTFLAG_RXSTP) {
			_usb_d_dev_handle_setup(ept);
		}
	}
}

/**
 * \brief Handles the endpoint interrupts.
 * \param[in] epint Endpoint interrupt summary (by bits).
 * \param[in] ept Pointer to endpoint information.
 */
static inline void _usb_d_dev_handle_eps(uint32_t epint, struct _usb_d_dev_ep *ept)
{
	Usb *hw = USB;

	uint8_t flags, mask;
	uint8_t epn = USB_EP_GET_N(ept->ep);

	if (!(epint & (1u << epn))) {
		return;
	}
	flags = hw->DEVICE.DeviceEndpoint[epn].EPINTFLAG.reg;
	mask  = hw->DEVICE.DeviceEndpoint[epn].EPINTENSET.reg;
	flags &= mask;
	if (flags) {
		if ((ept->flags.bits.eptype == 0x1) && !_usb_d_dev_ep_is_busy(ept)) {
			_usb_d_dev_trans_setup_isr(ept, flags);
		} else if (_usb_d_dev_ep_is_in(ept)) {
			_usb_d_dev_trans_in_isr(ept, flags);
		} else {
			_usb_d_dev_trans_out_isr(ept, flags);
		}
	}
}

/**
 * \brief USB device interrupt handler
 * \param[in] unused The parameter is not used
 */
static void _usb_d_dev_handler(void)
{
	Usb *   hw = USB;
	uint8_t i;

	uint16_t epint = hw->DEVICE.EPINTSMRY.reg;
	if (0 == epint) {
		if (_usb_d_dev_handle_nep()) {
			return;
		}
	}
	/* Handle endpoints */
	for (i = 0; i < USB_D_N_EP; i++) {
		struct _usb_d_dev_ep *ept = &dev_inst.ep[i];
		if (ept->ep == 0xFF) {
			continue;
		}
		_usb_d_dev_handle_eps(epint, ept);
	}
}

/**
 * \brief Reset all endpoint software instances
 */
static void _usb_d_dev_reset_epts(void)
{
	uint8_t i;
	for (i = 0; i < USB_D_N_EP; i++) {
		_usb_d_dev_trans_done(&dev_inst.ep[i], USB_TRANS_RESET);
		dev_inst.ep[i].ep       = 0xFF;
		dev_inst.ep[i].flags.u8 = 0;
	}
	memset(prvt_inst.desc_table, 0, sizeof(UsbDeviceDescriptor) * (CONF_USB_D_MAX_EP_N + 1));
}

int32_t _usb_d_dev_init(void)
{
	Usb *         hw         = USB;
	uint8_t       speed      = CONF_USB_D_SPEED;
	const uint8_t spdconf[4] = {
	    USB_DEVICE_CTRLB_SPDCONF(1), /* LS */
	    USB_DEVICE_CTRLB_SPDCONF(0), /* FS */
	    0,
	    0 /* Reserved */
	};

	hri_usbdevice_wait_for_sync(hw, USB_SYNCBUSY_SWRST);
	if (hri_usbdevice_get_CTRLA_ENABLE_bit(hw)) {
		return ERR_DENIED;
	}
	hri_usbdevice_set_CTRLA_SWRST_bit(hw);
	hri_usbdevice_wait_for_sync(hw, USB_SYNCBUSY_SWRST);

	dev_inst.callbacks.sof   = (_usb_d_dev_sof_cb_t)_dummy_func_no_return;
	dev_inst.callbacks.event = (_usb_d_dev_event_cb_t)_dummy_func_no_return;

	dev_inst.ep_callbacks.setup = (_usb_d_dev_ep_cb_setup_t)_dummy_func_no_return;
	dev_inst.ep_callbacks.more  = (_usb_d_dev_ep_cb_more_t)_dummy_func_no_return;
	dev_inst.ep_callbacks.done  = (_usb_d_dev_ep_cb_done_t)_dummy_func_no_return;

	_usb_d_dev_reset_epts();

	_usb_load_calib();

	hri_usbdevice_write_CTRLA_reg(hw, USB_CTRLA_RUNSTDBY);
	hri_usbdevice_write_DESCADD_reg(hw, (uint32_t)prvt_inst.desc_table);
	hri_usbdevice_write_CTRLB_reg(hw, spdconf[speed] | USB_DEVICE_CTRLB_DETACH);

	return ERR_NONE;
}

void _usb_d_dev_deinit(void)
{
	Usb *hw = USB;

	while (_usb_d_dev_disable() < 0)
		;

	hri_usbdevice_write_CTRLA_reg(hw, USB_CTRLA_SWRST);

	NVIC_DisableIRQ(USB_0_IRQn);
	NVIC_ClearPendingIRQ(USB_0_IRQn);
	NVIC_DisableIRQ(USB_1_IRQn);
	NVIC_ClearPendingIRQ(USB_1_IRQn);
	NVIC_DisableIRQ(USB_2_IRQn);
	NVIC_ClearPendingIRQ(USB_2_IRQn);
	NVIC_DisableIRQ(USB_3_IRQn);
	NVIC_ClearPendingIRQ(USB_3_IRQn);
}

int32_t _usb_d_dev_enable(void)
{
	Usb *   hw = USB;
	uint8_t ctrla;

	if (hri_usbdevice_get_SYNCBUSY_reg(hw, (USB_SYNCBUSY_ENABLE | USB_SYNCBUSY_SWRST))) {
		return -USB_ERR_DENIED;
	}
	ctrla = hri_usbdevice_read_CTRLA_reg(hw);
	if ((ctrla & USB_CTRLA_ENABLE) == 0) {
		hri_usbdevice_write_CTRLA_reg(hw, ctrla | USB_CTRLA_ENABLE);
	}

	NVIC_EnableIRQ(USB_0_IRQn);
	NVIC_EnableIRQ(USB_1_IRQn);
	NVIC_EnableIRQ(USB_2_IRQn);
	NVIC_EnableIRQ(USB_3_IRQn);

	hri_usbdevice_set_INTEN_reg(hw,
	                            USB_DEVICE_INTENSET_SOF | USB_DEVICE_INTENSET_EORST | USB_DEVICE_INTENSET_RAMACER
	                                | USB_D_SUSPEND_INT_FLAGS);

	return ERR_NONE;
}

int32_t _usb_d_dev_disable(void)
{
	Usb *   hw = USB;
	uint8_t ctrla;

	if (hri_usbdevice_get_SYNCBUSY_reg(hw, (USB_SYNCBUSY_ENABLE | USB_SYNCBUSY_SWRST))) {
		return -USB_ERR_DENIED;
	}

	ctrla = hri_usbdevice_read_CTRLA_reg(hw);
	if (ctrla & USB_CTRLA_ENABLE) {
		hri_usbdevice_write_CTRLA_reg(hw, ctrla & ~USB_CTRLA_ENABLE);
	}

	NVIC_DisableIRQ(USB_0_IRQn);
	NVIC_DisableIRQ(USB_1_IRQn);
	NVIC_DisableIRQ(USB_2_IRQn);
	NVIC_DisableIRQ(USB_3_IRQn);

	hri_usbdevice_clear_INTEN_reg(hw,
	                              USB_DEVICE_INTENSET_SOF | USB_DEVICE_INTENSET_EORST | USB_DEVICE_INTENSET_RAMACER
	                                  | USB_D_SUSPEND_INT_FLAGS
	                                  | USB_D_WAKEUP_INT_FLAGS);

	return ERR_NONE;
}

void _usb_d_dev_attach(void)
{
	hri_usbdevice_clear_CTRLB_DETACH_bit(USB);
}

void _usb_d_dev_detach(void)
{
	hri_usbdevice_set_CTRLB_DETACH_bit(USB);
}

#ifndef USB_FSMSTATUS_FSMSTATE_ON
#define USB_FSMSTATUS_FSMSTATE_ON USB_FSMSTATUS_FSMSTATE(2ul)
#endif
void _usb_d_dev_send_remotewakeup(void)
{
	uint32_t retry = CONF_USB_RMT_WKUP_RETRY;
	_usb_d_dev_wait_clk_rdy(CONF_USB_D_CLK_SRC);
	while ((USB_FSMSTATUS_FSMSTATE_ON != hri_usbdevice_read_FSMSTATUS_FSMSTATE_bf(USB)) && (retry--)) {
		USB->DEVICE.CTRLB.bit.UPRSM = 1;
	}
}

enum usb_speed _usb_d_dev_get_speed(void)
{
	uint8_t              sp       = (enum usb_speed)hri_usbdevice_read_STATUS_SPEED_bf(USB);
	const enum usb_speed speed[2] = {USB_SPEED_FS, USB_SPEED_LS};

	return speed[sp];
}

void _usb_d_dev_set_address(uint8_t addr)
{
	hri_usbdevice_write_DADD_reg(USB, USB_DEVICE_DADD_ADDEN | USB_DEVICE_DADD_DADD(addr));
}

uint8_t _usb_d_dev_get_address(void)
{
	uint8_t addr = hri_usbdevice_read_DADD_DADD_bf(USB);
	return addr;
}

uint16_t _usb_d_dev_get_frame_n(void)
{
	uint16_t fn = hri_usbdevice_read_FNUM_FNUM_bf(USB);
	return fn;
}

uint8_t _usb_d_dev_get_uframe_n(void)
{
	uint8_t ufn = hri_usbdevice_read_FNUM_MFNUM_bf(USB);
	return ufn;
}

/**
 *  \brief Start a setup transaction
 *  \param[in] ept Endpoint information.
 */
static inline void _usb_d_dev_trans_setup(struct _usb_d_dev_ep *ept)
{
	Usb *   hw  = USB;
	uint8_t epn = USB_EP_GET_N(ept->ep);

	_usbd_ep_set_buf(epn, 0, (uint32_t)ept->cache);
	_usbd_ep_set_out_trans(epn, 0, ept->size, 0);

	hri_usbendpoint_clear_EPSTATUS_reg(hw, epn, USB_DEVICE_EPSTATUS_STALLRQ(0x3) | USB_DEVICE_EPSTATUS_BK1RDY);
	_usbd_ep_set_out_rdy(epn, 0, false);

	hri_usbendpoint_set_EPINTEN_reg(hw, epn, USB_D_SETUP_INT_FLAGS);
}

int32_t _usb_d_dev_ep0_init(const uint8_t max_pkt_siz)
{
	return _usb_d_dev_ep_init(0, USB_EP_XTYPE_CTRL, max_pkt_siz);
}

int32_t _usb_d_dev_ep_init(const uint8_t ep, const uint8_t attr, const uint16_t max_pkt_siz)
{
	uint8_t               epn = USB_EP_GET_N(ep);
	bool                  dir = USB_EP_GET_DIR(ep);
	struct _usb_d_dev_ep *ept = _usb_d_dev_ept(epn, dir);

	uint8_t                        ep_type = attr & USB_EP_XTYPE_MASK;
	const struct _usb_ep_cfg_item *pcfg    = &_usb_ep_cfgs[epn];

	if (epn > CONF_USB_D_MAX_EP_N) {
		return -USB_ERR_PARAM;
	}
	if (ept->ep != 0xFF) {
		return -USB_ERR_REDO;
	}
	if (ep_type == USB_EP_XTYPE_CTRL) {
		struct _usb_d_dev_ep *ept_in = _usb_d_dev_ept(epn, !dir);
		if (ept_in->ep != 0xFF) {
			return -USB_ERR_REDO;
		}
		if (pcfg->cache == NULL) {
			return -USB_ERR_FUNC;
		}
	}
	if ((dir ? pcfg->i_cache : pcfg->cache) && ((dir ? pcfg->i_size : pcfg->size) < max_pkt_siz)) {
		return -USB_ERR_FUNC;
	}

	/* Initialize EP n settings */
	ept->cache    = (uint8_t *)(dir ? pcfg->i_cache : pcfg->cache);
	ept->size     = max_pkt_siz;
	ept->flags.u8 = (ep_type + 1);
	ept->ep       = ep;

	return USB_OK;
}

void _usb_d_dev_ep_deinit(uint8_t ep)
{
	Usb *                 hw  = USB;
	uint8_t               epn = USB_EP_GET_N(ep);
	bool                  dir = USB_EP_GET_DIR(ep);
	struct _usb_d_dev_ep *ept = _usb_d_dev_ept(epn, dir);

	if (epn > CONF_USB_D_MAX_EP_N || !_usb_d_dev_ep_is_used(ept)) {
		return;
	}

	/* Finish pending transactions. */
	_usb_d_dev_trans_stop(ept, dir, USB_TRANS_RESET);

	/* Disable the endpoint. */
	if (_usb_d_dev_ep_is_ctrl(ept)) {
		hw->DEVICE.DeviceEndpoint[ep].EPCFG.reg = 0;
	} else if (USB_EP_GET_DIR(ep)) {
		hw->DEVICE.DeviceEndpoint[USB_EP_GET_N(ep)].EPCFG.reg &= ~USB_DEVICE_EPCFG_EPTYPE1_Msk;
	} else {
		hw->DEVICE.DeviceEndpoint[ep].EPCFG.reg &= ~USB_DEVICE_EPCFG_EPTYPE0_Msk;
	}
	ept->flags.u8 = 0;
	ept->ep       = 0xFF;
}

int32_t _usb_d_dev_ep_enable(const uint8_t ep)
{
	Usb *                 hw    = USB;
	uint8_t               epn   = USB_EP_GET_N(ep);
	bool                  dir   = USB_EP_GET_DIR(ep);
	struct _usb_d_dev_ep *ept   = _usb_d_dev_ept(epn, dir);
	uint8_t               epcfg = hri_usbendpoint_read_EPCFG_reg(hw, epn);
	UsbDeviceDescBank *   bank;

	if (epn > CONF_USB_D_MAX_EP_N || !_usb_d_dev_ep_is_used(ept)) {
		return -USB_ERR_PARAM;
	}

	bank = prvt_inst.desc_table[epn].DeviceDescBank;
	if (ept->flags.bits.eptype == USB_D_EPTYPE_CTRL) {
		if (epcfg & (USB_DEVICE_EPCFG_EPTYPE1_Msk | USB_DEVICE_EPCFG_EPTYPE0_Msk)) {
			return -USB_ERR_REDO;
		}
		hri_usbendpoint_write_EPCFG_reg(hw, epn, USB_D_EPCFG_CTRL);
		bank[0].PCKSIZE.reg = USB_DEVICE_PCKSIZE_MULTI_PACKET_SIZE(ept->size)
		                      | USB_DEVICE_PCKSIZE_SIZE(_usbd_ep_pcksize_size(ept->size));
		bank[1].PCKSIZE.reg
		    = USB_DEVICE_PCKSIZE_BYTE_COUNT(ept->size) | USB_DEVICE_PCKSIZE_SIZE(_usbd_ep_pcksize_size(ept->size));
		/* By default, control endpoint accept SETUP and NAK all other token. */
		_usbd_ep_set_out_rdy(epn, 0, false);
		_usbd_ep_set_in_rdy(epn, 1, false);

		_usbd_ep_clear_bank_status(epn, 0);
		_usbd_ep_clear_bank_status(epn, 1);

		/* Enable SETUP reception for control endpoint. */
		_usb_d_dev_trans_setup(ept);

	} else if (dir) {
		if (epcfg & USB_DEVICE_EPCFG_EPTYPE1_Msk) {
			return -USB_ERR_REDO;
		}
		epcfg |= USB_DEVICE_EPCFG_EPTYPE1(ept->flags.bits.eptype);
		hri_usbendpoint_write_EPCFG_reg(hw, epn, epcfg);

		bank[1].PCKSIZE.reg
		    = USB_DEVICE_PCKSIZE_BYTE_COUNT(ept->size) | USB_DEVICE_PCKSIZE_SIZE(_usbd_ep_pcksize_size(ept->size));

		/* By default, IN endpoint will NAK all token. */
		_usbd_ep_set_in_rdy(epn, 1, false);
		_usbd_ep_clear_bank_status(epn, 1);

	} else {

		if (epcfg & USB_DEVICE_EPCFG_EPTYPE0_Msk) {
			return -USB_ERR_REDO;
		}
		epcfg |= USB_DEVICE_EPCFG_EPTYPE0(ept->flags.bits.eptype);
		hri_usbendpoint_write_EPCFG_reg(hw, epn, epcfg);

		bank[0].PCKSIZE.reg = USB_DEVICE_PCKSIZE_MULTI_PACKET_SIZE(ept->size)
		                      | USB_DEVICE_PCKSIZE_SIZE(_usbd_ep_pcksize_size(ept->size));

		/* By default, OUT endpoint will NAK all token. */
		_usbd_ep_set_out_rdy(epn, 0, false);
		_usbd_ep_clear_bank_status(epn, 0);
	}

	return USB_OK;
}

void _usb_d_dev_ep_disable(const uint8_t ep)
{
	Usb *                 hw  = USB;
	uint8_t               epn = USB_EP_GET_N(ep);
	bool                  dir = USB_EP_GET_DIR(ep);
	struct _usb_d_dev_ep *ept = _usb_d_dev_ept(epn, dir);

	_usb_d_dev_trans_stop(ept, dir, USB_TRANS_RESET);
	if (_usb_d_dev_ep_is_ctrl(ept)) {
		hri_usbendpoint_clear_EPINTEN_reg(hw, epn, USB_D_ALL_INT_FLAGS);
	}
}

/**
 * \brief Get endpoint stall status
 * \param[in] ept Pointer to endpoint information.
 * \param[in] dir Endpoint direction.
 * \return Stall status.
 * \retval \c true Endpoint is stalled.
 * \retval \c false Endpoint is not stalled.
 */
static inline int32_t _usb_d_dev_ep_stall_get(struct _usb_d_dev_ep *ept, bool dir)
{
	uint8_t epn = USB_EP_GET_N(ept->ep);
	return _usbd_ep_is_stalled(epn, dir);
}

/**
 * \brief Set endpoint stall
 * \param[in, out] ept Pointer to endpoint information.
 * \param[in] dir Endpoint direction.
 * \return Always 0, success.
 */
static inline int32_t _usb_d_dev_ep_stall_set(struct _usb_d_dev_ep *ept, bool dir)
{
	uint8_t epn = USB_EP_GET_N(ept->ep);
	_usbd_ep_set_stall(epn, dir, true);
	_usbd_ep_int_en(epn, USB_DEVICE_EPINTFLAG_STALL0 << dir);
	ept->flags.bits.is_stalled = 1;
	/* In stall interrupt abort the transfer. */
	return ERR_NONE;
}

/**
 * \brief Clear endpoint stall
 * \param[in, out] ept Pointer to endpoint information.
 * \param[in] dir Endpoint direction.
 * \return Always 0, success.
 */
static inline int32_t _usb_d_dev_ep_stall_clr(struct _usb_d_dev_ep *ept, bool dir)
{
	uint8_t epn        = USB_EP_GET_N(ept->ep);
	bool    is_stalled = _usbd_ep_is_stalled(epn, dir);
	if (!is_stalled) {
		return ERR_NONE;
	}
	_usbd_ep_set_stall(epn, dir, false);
	_usbd_ep_int_dis(epn, USB_DEVICE_EPINTFLAG_STALL0 << dir);
	if (_usbd_ep_is_stall_sent(epn, dir)) {
		_usbd_ep_ack_stall(epn, dir);
		_usbd_ep_set_toggle(epn, dir, 0);
	}
	if (_usb_d_dev_ep_is_ctrl(ept)) {
		if ((hri_usbendpoint_read_EPSTATUS_reg(USB, epn) & USB_DEVICE_EPSTATUS_STALLRQ_Msk) == 0) {
			ept->flags.bits.is_stalled = 0;
		}
	} else {
		ept->flags.bits.is_stalled = 0;
	}
	return ERR_NONE;
}

int32_t _usb_d_dev_ep_stall(const uint8_t ep, const enum usb_ep_stall_ctrl ctrl)
{
	uint8_t               epn = USB_EP_GET_N(ep);
	bool                  dir = USB_EP_GET_DIR(ep);
	struct _usb_d_dev_ep *ept = _usb_d_dev_ept(epn, dir);
	int32_t               rc;

	if (epn > CONF_USB_D_MAX_EP_N) {
		return -USB_ERR_PARAM;
	}

	if (USB_EP_STALL_SET == ctrl) {
		rc = _usb_d_dev_ep_stall_set(ept, dir);
	} else if (USB_EP_STALL_CLR == ctrl) {
		rc = _usb_d_dev_ep_stall_clr(ept, dir);
	} else {
		rc = _usb_d_dev_ep_stall_get(ept, dir);
	}
	return rc;
}

/**
 *  \brief Finish the transaction and invoke callback
 * \param[in, out] ept Pointer to endpoint information.
 * \param[in] code Information code passed.
 */
static void _usb_d_dev_trans_done(struct _usb_d_dev_ep *ept, const int32_t code)
{
	if (!(_usb_d_dev_ep_is_used(ept) && _usb_d_dev_ep_is_busy(ept))) {
		return;
	}
	ept->flags.bits.is_busy = 0;
	dev_inst.ep_callbacks.done(ept->ep, code, ept->trans_count);
}

/**
 *  \brief Terminate the transaction with specific status code
 * \param[in, out] ept Pointer to endpoint information.
 * \param[in] dir Endpoint direction.
 * \param[in] code Information code passed.
 */
static void _usb_d_dev_trans_stop(struct _usb_d_dev_ep *ept, bool dir, const int32_t code)
{
	uint8_t epn = USB_EP_GET_N(ept->ep);
	;
	const uint8_t intflags[2] = {USB_D_BANK0_INT_FLAGS, USB_D_BANK1_INT_FLAGS};
	if (!(_usb_d_dev_ep_is_used(ept) && _usb_d_dev_ep_is_busy(ept))) {
		return;
	}
	/* Stop transfer */
	if (dir) {
		/* NAK IN */
		_usbd_ep_set_in_rdy(epn, 1, false);
	} else {
		/* NAK OUT */
		_usbd_ep_set_out_rdy(epn, 0, false);
	}
	_usbd_ep_int_ack(epn, intflags[dir]);
	_usbd_ep_int_dis(epn, intflags[dir]);
	_usb_d_dev_trans_done(ept, code);
}

int32_t _usb_d_dev_ep_read_req(const uint8_t ep, uint8_t *req_buf)
{
	uint8_t            epn   = USB_EP_GET_N(ep);
	UsbDeviceDescBank *bank  = prvt_inst.desc_table[epn].DeviceDescBank;
	uint32_t           addr  = bank[0].ADDR.reg;
	uint16_t           bytes = bank[0].PCKSIZE.bit.BYTE_COUNT;

	if (epn > CONF_USB_D_MAX_EP_N || !req_buf) {
		return -USB_ERR_PARAM;
	}
	if (!_usbd_ep_is_ctrl(epn)) {
		return -USB_ERR_FUNC;
	}
	if (!_usbd_ep_is_setup(epn)) {
		return ERR_NONE;
	}
	memcpy(req_buf, (void *)addr, 8);
	_usbd_ep_ack_setup(epn);

	return bytes;
}

int32_t _usb_d_dev_ep_trans(const struct usb_d_transfer *trans)
{
	uint8_t               epn = USB_EP_GET_N(trans->ep);
	bool                  dir = USB_EP_GET_DIR(trans->ep);
	struct _usb_d_dev_ep *ept = _usb_d_dev_ept(epn, dir);

	uint16_t size_mask      = (ept->size == 1023) ? 1023 : (ept->size - 1);
	bool     size_n_aligned = (trans->size & size_mask);

	bool use_cache = false;

	volatile hal_atomic_t flags;

	if (epn > CONF_USB_D_MAX_EP_N) {
		return -USB_ERR_PARAM;
	}

	/* Cases that needs cache:
	 * 1. Buffer not in RAM (cache all).
	 * 2. IN/OUT with unaligned buffer (cache all).
	 * 3. OUT with unaligned packet size (cache last packet).
	 * 4. OUT size < 8 (sub-case for 3).
	 */
	if (!_usb_is_addr4dma(trans->buf, trans->size) || (!_usb_is_aligned(trans->buf))
	    || (!dir && (trans->size < ept->size))) {
		if (!ept->cache) {
			return -USB_ERR_FUNC;
		}
		/* Use cache all the time. */
		use_cache = true;
	}
	if (!dir && size_n_aligned) {
		if (!ept->cache) {
			return -USB_ERR_PARAM;
		}
		/* Set 'use_cache' on last packet. */
	}

	/* Check halt */
	if (ept->flags.bits.is_stalled) {
		return USB_HALTED;
	}

	/* Try to start transactions. */

	atomic_enter_critical(&flags);
	if (_usb_d_dev_ep_is_busy(ept)) {
		atomic_leave_critical(&flags);
		return USB_BUSY;
	}
	ept->flags.bits.is_busy = 1;
	atomic_leave_critical(&flags);

	/* Copy transaction information. */
	ept->trans_buf   = trans->buf;
	ept->trans_size  = trans->size;
	ept->trans_count = 0;

	ept->flags.bits.dir       = dir;
	ept->flags.bits.use_cache = use_cache;
	ept->flags.bits.need_zlp  = (trans->zlp && (!size_n_aligned));

	if (dir) {
		_usb_d_dev_in_next(ept, false);
	} else {
		_usb_d_dev_out_next(ept, false);
	}

	return ERR_NONE;
}

void _usb_d_dev_ep_abort(const uint8_t ep)
{
	uint8_t               epn = USB_EP_GET_N(ep);
	bool                  dir = USB_EP_GET_DIR(ep);
	struct _usb_d_dev_ep *ept = _usb_d_dev_ept(epn, dir);
	if (epn > CONF_USB_D_MAX_EP_N) {
		return;
	}
	_usb_d_dev_trans_stop(ept, dir, USB_TRANS_ABORT);
}

int32_t _usb_d_dev_ep_get_status(const uint8_t ep, struct usb_d_trans_status *stat)
{
	uint8_t               epn = USB_EP_GET_N(ep);
	bool                  dir = USB_EP_GET_DIR(ep);
	struct _usb_d_dev_ep *ept = _usb_d_dev_ept(epn, dir);
	bool                  busy, stall;

	if (epn > CONF_USB_D_MAX_EP_N) {
		return USB_ERR_PARAM;
	}
	busy  = ept->flags.bits.is_busy;
	stall = ept->flags.bits.is_stalled;
	if (stat) {
		stat->stall = stall;
		stat->busy  = busy;
		stat->setup = USB->DEVICE.DeviceEndpoint[epn].EPINTFLAG.bit.RXSTP;
		stat->dir   = ept->flags.bits.dir;
		stat->size  = ept->trans_size;
		stat->count = ept->trans_count;
		stat->ep    = ep;
		stat->xtype = ept->flags.bits.eptype - 1;
	}
	if (stall) {
		return USB_HALTED;
	}
	if (busy) {
		return USB_BUSY;
	}
	return USB_OK;
}

void _usb_d_dev_register_callback(const enum usb_d_cb_type type, const FUNC_PTR func)
{
	FUNC_PTR f = (func == NULL) ? (FUNC_PTR)_dummy_func_no_return : (FUNC_PTR)func;
	if (type == USB_D_CB_EVENT) {
		dev_inst.callbacks.event = (_usb_d_dev_event_cb_t)f;
	} else if (type == USB_D_CB_SOF) {
		dev_inst.callbacks.sof = (_usb_d_dev_sof_cb_t)f;
	}
}

void _usb_d_dev_register_ep_callback(const enum usb_d_dev_ep_cb_type type, const FUNC_PTR func)
{
	FUNC_PTR f = (func == NULL) ? (FUNC_PTR)_dummy_func_no_return : (FUNC_PTR)func;
	if (type == USB_D_DEV_EP_CB_SETUP) {
		dev_inst.ep_callbacks.setup = (_usb_d_dev_ep_cb_setup_t)f;
	} else if (type == USB_D_DEV_EP_CB_MORE) {
		dev_inst.ep_callbacks.more = (_usb_d_dev_ep_cb_more_t)f;
	} else if (type == USB_D_DEV_EP_CB_DONE) {
		dev_inst.ep_callbacks.done = (_usb_d_dev_ep_cb_done_t)f;
	}
}

/**
* \brief USB interrupt handler
*/
void USB_0_Handler(void)
{

	_usb_d_dev_handler();
}
/**
* \brief USB interrupt handler
*/
void USB_1_Handler(void)
{

	_usb_d_dev_handler();
}
/**
* \brief USB interrupt handler
*/
void USB_2_Handler(void)
{

	_usb_d_dev_handler();
}
/**
* \brief USB interrupt handler
*/
void USB_3_Handler(void)
{

	_usb_d_dev_handler();
}
